期刊,Environmental and experimental botany 2022年196卷期_国家学术搜索

期刊信息/Journal information

Environmental and experimental botany

Pergamon Press,

主办单位：Pergamon Press,

国际刊号：0098-8472

Environmental and experimental botany/Journal Environmental and experimental botanySCIISTP

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Mechanisms for increased pH-mediated amelioration of copper toxicity in Citrus sinensis leaves using physiology, transcriptomics and metabolomics

Zhang, JiangChen, Xu-FengHuang, Wei-TaoChen, Huan-Huan...

16页

查看更多>>摘要：Limited data are available on the molecular and physiological mechanisms for increased pH-mediated amelioration of copper (Cu) toxicity in plants. Citrus sinensis seedlings were fertilized with a nutrient solution at the Cu concentration of 300 (Cu toxicity) or 0.5 mu M (control) and a pH of 3.0, 4.0, or 4.8 for 17 weeks. Subsequently, we examined the interactive effects of low pH and Cu toxicity on transcriptomics, metabolomics, and some physiological parameters in leaves. Our results demonstrated that increased pH reduced Cu toxicity-induced leaf Cu accumulation and oxidative damage by reducing reactive oxygen species (ROS) production and maintaining the homeostasis of sulfur (S)-containing compounds (reduced glutathione), ascorbate, and cell redox potential, thus mitigating Cu toxic effects on leaf chlorophyll biosynthesis, photosynthesis, and metabolisms of carbohydrates, lipids, amino acids, and secondary metabolites. The increased pH mitigated Cu toxicity-induced impairment of cell wall metabolism by reducing cell wall Cu concentration, thus improving leaf growth. Under low pH (pH 3.0), C. sinensis leaves also displayed some adaptive responses to Cu toxicity to meet the increased demand for the dissipation of excess light energy and the detoxification of Cu and ROS, including: (a) increased distribution of Cu in cell wall; (b) elevated photorespiration and thermal dissipation; (c) increased accumulation of nonstructural carbohydrates [fructose, glucose, starch, total nonstructural carbohydrates (the summation of fructose + glucose + sucrose + starch), maltotetraose and 1,1-kestotetraose] and upregulation of metabolism (glycolysis/ gluconeogenesis, pyruvate metabolism and pentose phosphate pathway) related to energy production; (d) downregulation of phospholipid [LysoPC 18:3(2 n isomer)] and phosphate-containing compounds (2 '-deoxycytidine-5 '-monophosphate and adenosine 5 '-monophosphate) and upregulation of L-tryptophan metabolism and related amino acids (L-tryptophan and 5-hydroxy-L-tryptophan); and (e) increased accumulation of some secondary metabolites [total phenolics, lignin, alkaloids (3-indoleacrylic acid, N-acetyl-5-hydroxytryptamine and methyl nicotinate), plumerane (indole and 3-indolepropionic acid) and coumarins (isoscopoletin, scopoletin, skimming and scopolin)]. However, these adaptive responses could not protect low pH-treated leaves from Cu toxicity, as indicated by elevated malondialdehyde accumulation and electrolyte leakage and decreased photosynthesis and chlorophyll level in leaves as well as reduced leaf growth due to impaired cell metabolism. Cu toxicity intensified the adverse effects of low pH on C. sinensis leaves.

原文链接:

NSTL
Elsevier

The barley mutant happy under the sun 1 (hus1): An additional contribution to pale green crops

Savin, RoxanaRossini, LauraTondelli, AlessandroJaniak, Agnieszka...

21页

查看更多>>摘要：Truncated antenna size of photosystems and lower leaf chlorophyll content has been shown to increase photosynthetic efficiency and biomass accumulation in microalgae, cyanobacteria and higher plants grown under high density cultivation conditions. Here, we have asked whether this strategy is also applicable to a major crop by characterizing the barley mutant happy under the sun 1 (hus1). The pale green phenotype of hus1 is due to a 50% reduction in the chlorophyll content of leaves, owing to a premature stop codon in the HvcpSRP43 gene for the 43-kDa chloroplast Signal Recognition Particle (cpSRP43). The HvcpSRP43 protein is responsible for the uploading of photosystem antenna proteins into the thylakoid membranes, and its truncation results in a smaller photosystem antenna size. Besides a detailed molecular and physiological characterization of the mutant grown under controlled greenhouse conditions, we show that the agronomic performance of hus1 plants, in terms of total biomass production and grain yield under standard field conditions, is comparable to that of control plants. The results are discussed in terms of the potential benefits of the hus1 phenotype, and of natural allelic variants of the HvcpSRP43 locus, with respect to productivity and mitigation of climate change.

原文链接:

NSTL
Elsevier

Development of melatonin nano-delivery systems to reduce cadmium accumulation in rice (Oryza sativa L.) seedlings: Insights from photosynthetic efficiency, antioxidative response and gene expression

Chen, JunqiaoQin, HongZhang, BaofengMao, Weihua...

12页

查看更多>>摘要：Cadmium (Cd) contamination in paddy soil has become a worldwide problem for rice production. Foliar application has been reported as a practical approach to reducing Cd accumulation in rice. In the present study, we used mesoporous silica nanoparticles (MSN) and MSN-chitosan (MSN-CS) as carriers to deliver melatonin (MT) into rice plants through foliar spray. Both systems showed the potentials as controlled-release delivery vehicles, with MT@MSN-CS performing better in vitro. The hydroponic trial revealed that foliar spray of MT@MSN-CS could significantly reduce Cd concentration in rice leaves by 43.8%, which was better than those of MT and MT@MSN. The nano-delivery systems improved leaf photosynthesis efficiency, decreased malondialdehyde (MDA) content, enhanced the activity of antioxidative enzymes including superoxide dismutase (SOD), peroxidase (POD), catalase (CAT) and ascorbate peroxidase (APX), as well as regulated the expression levels of Cd transport genes (OsNramp1, OsNramp5, OsHMA2, OsHMA3, OsLCD and OsPCR1). Our results also suggested that the use of stimuli-responsive carriers, MSN-CS, for example, as MT-delivery systems may be a feasible option for the reduction of heavy metal accumulation in plants and can be potentially implemented in soil remediation.

原文链接:

NSTL
Elsevier

Hydrometeorology for plant omics: Potential evaporation as a key index for transcriptome in rice

Maruyama, AtsushiIshida, SachinobuKuwagata, TsuneoMurai-Hatano, Mari...

14页

查看更多>>摘要：Transpiration is a major physiological phenomenon in plants and is induced by atmospheric transpirational demand. However, little is known about quantitative relationships between transpirational demand and multiple meteorological factors, and how plants respond to short-time (day-to-day) changes in transpirational demand at the gene and molecular levels. We used a physical-based model of heat balance and transfer at a saturated surface to quantify the sensitivity of potential evaporation (Ep; a hydrometeorological indicator of transpirational demand) to each meteorological factor under a wide range of climatic conditions. Sensitivity analysis showed that Ep varies dynamically in time and space with meteorological conditions. That is, Ep changes commensurately with solar radiation Sd, somewhat increases with wind speed WS, while somewhat decreases with increasing relative humidity Rh. The sensitivity of Ep to WS and Rh increases with decreasing Sd. The logarithm of Ep decreases approximately linearly with increasing inverse absolute temperature. The validity of use of Ep as the transpirational demand under natural field conditions was confirmed by high correlation between hourly based Ep and hourly evapotranspiration in the flooded rice paddy fields. We also examined the effects of short-term changes in Ep on transpiration (ET) and transcriptomes of rice at the heading stage by altering meteorological conditions on sunny days for four hours. ET changed commensurately with Ep, and the expression levels of numerous genes, including those encoding aquaporins in rice leaves and roots, showed a significant positive or negative correlation with ET, especially in leaves. The present study suggests that rice plants may adjust their physiological condition, such as hydraulic conductivity and mesophyll conductance, through dynamic transcriptome changes in response to transpirational demand under fluctuating meteorological conditions.

原文链接:

NSTL
Elsevier

Auxin-mediated molecular mechanisms of heavy metal and metalloid stress regulation in plants

Mathur, PiyushTripathi, Durgesh KumarBalus, FrantisekMukherjee, Soumya...

17页

查看更多>>摘要：Expeditious industrial development has prompted the upraised production and release of colossal amounts of various heavy metals (HMs) and metalloids in the environment. Heavy metal stress (HMS) intimidates crop production and threatens global food security. After their uptake in plants, various plant responses are stimulated to deal with heavy metal or metalloid stress including the elevated synthesis of auxin plant hormone. Latest researches have marked the potential of auxin in imparting resilience to these stresses in plants mostly via reducing their uptake, promoting their chelation and vacuolar sequestration in plant tissues and alleviating the stress-induced oxidative damage. Furthermore, auxin exhibits crosstalk with various other biomolecules like nitric oxide (NO), carbon monoxide (CO), ethylene (Et), salicylic acid (SA) and abscisic acid (ABA) which in turn protect the plants from oxidative stress generated from different stressful conditions. Regulation of the genes and transcription factors associated with auxin signaling provides a clue to the molecular signaling responses associated with heavy metal and metalloid stress. Although various investigations report the role of hydrogen sulfide (H2S) in mitigation of various abiotic stresses, no substantial evidence deciphers the possible role of auxin-H2S crosstalk during HMs and metalloid stress in plants. In this context, it is important to extend our understanding on the integrative role of auxin, carbon monoxide (CO) and hydrogen sulfide (H2S) during HM and metalloid stress in plants. Various other biomolecules like strigolactones (SLs), melatonin and polyamines are expected to be associated with auxin-mediated signaling during HM and metalloid stress. Although persuasive at present, future investigations are necessary to bring about a comprehensive understanding of auxin stimulated biological responses at physiological and molecular levels.

原文链接:

NSTL
Elsevier

Regulation of accumulation and metabolism circadian rhythms of starch and sucrose in two leaf-color lettuces by red:blue ratios of LED continuous light

Liu, JiayuanLiu, Wenke

11页

查看更多>>摘要：There are interspecies differences in lettuce CL tolerance to LED red and blue light. It is important to clarify the response mechanism of tolerant and sensitive lettuce to CL to achieve efficient application of CL in artificial light plant factories. In the experiment, red-blue LEDs were used to provide a conventional light (360 mu mol.m(-2).s(-1), red:blue ratio 4:1 and 18/6 h photoperiod) and three continuous light (CL) treatments with various red:blue ratios (270 mu mol.m(-2).s(-1), red:blue ratio 4:1, 2:1 and 1:1) for CL-sensitive and tolerant lettuce cultivars (Yidali and Zishan) with the same daily light integral. The effects of CL quality on the growth, diurnal starch and sucrose accumulation and metabolism of two lettuces were studied by sampling at 6:00, 12:00, 18:00 and 24:00 on the 12 days after light treatment. The results showed that red-blue CL up-regulated shoot biomass of two cultivars, which might be attributed to root and leafy morphology, and chlorophyll content responses. CL with the 80% red light produced the greatest yield, but minor and medium leafy injury was found only on Yidali. CL improved starch and sucrose contents diurnally in two lettuce cultivars, and they totally decreased with blue light proportion. Sucrose synthase (SS), sucrose phosphate synthase (SPS), acid invertase (AI), neutral invertase (NI), adenosine diphosphate glucose pyrophosphorylas (AGP), alpha-amylase and 0-amylase activities under CL were improved in two lettuces compared with the conventional light. Starch and sucrose contents and SS, SPS and AGP activities basically decreased with blue light proportion for two cultivars, while AI, NI, alpha-amylase and 0-amylase activities increased inversely totally. CL irrespectively of its quality disordered the circadian rhythms of carbohydrate accumulation and metabolic enzyme activities in two lettuces. Starch content related closely positively with AGP, alpha-amylase and beta-amylase activities for Zishan, but positively AGP and beta-amylase activities for Yidali. Sucrose content correlated negatively with AI and NI activities for Zishan, while positively SS and SPS activities for Yidali. To sum up, red-blue CL with low-dose blue light could improve Yidali and Zishan lettuce yield, starch and sucrose accumulation, and metabolic enzyme activity, but CL disordered the circadian rhythms of carbohydrate accumulation and metabolic enzyme activity irrespectively of spectral quality. Yidali and Zishan lettuces are sensitive and tolerant cultivars to red-blue CL, which is not up to their abilities to maintain circadian rhythms of carbohydrate accumulation and metabolism. Furthermore, starch accumulation in two cultivars was controlled jointly by synthesis and decomposition enzymes, but sucrose accumulation in Yidali lettuce depended on decomposition enzymes rather than synthesis enzyme for purple lettuce.

原文链接:

NSTL
Elsevier

Application of RNA sequencing to understand the benefits of endophytes in the salt-alkaline resistance of rice seedlings

Ren, XiaoningShan, YuLi, XinFan, Jiahui...

12页

查看更多>>摘要：Endophytes significantly improve salt-alkaline resistance of rice seedlings and promote their growth, but the definite mechanisms remain largely unknown. This study aimed to understand the molecular players behind the endophytic benefits for rice seedlings under salt-alkaline stress. RNA sequencing (RNA-seq) was performed on the roots and shoots of rice seedling (Oryza sativa L.) with/without endophytic infection under 10 mM Na2CO3-treatment. The differential expression genes (DEGs) resulting from endophytic infection were analyzed, and the functions of DEGs were annotated using gene ontology (GO) enrichment and the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways. Results showed endophytic infection significantly promoted the growth of rice seedlings under salt-alkaline stress. Through RNA-seq, many genes were shown to be potentially involved in the endophytic benefits for rice seedlings. At one day of endophytic infection, RNA-seq identified 3469 DEGs in rice seedling roots and 572 DEGs in shoots, whereas five days of endophytic infection led to 297 and 257 DEGs in roots and shoots, respectively. According to the GO and KEGG annotation of DEGs, the growth-promotion processes correlating with the beneficial endophyte-rice interplay involve a multitude of molecular events, including biosynthesis, energy metabolism, enzyme activity, photosynthesis, ROS-scavenging system, and hormonal signaling, etc. Together, this work presents evidence of plant-microbe interaction that extends insights into the mechanisms underlying the endophyte-rice association.

原文链接:

NSTL
Elsevier

Carbon metabolic adjustment in soybean nodules in response to phosphate limitation: A metabolite perspective

Sulieman, SaadAbdelrahman, MostafaTran, Lam-Son Phan

13页

查看更多>>摘要：The necessity to gain deep insights regarding the overall metabolic efficiency of soybean functional acclimation to tackle phosphate (Pi) starvation has led us to discuss the current knowledge on the carbon (C) metabolic changes in soybean nodules under such Pi stress conditions in this review. Soybean possesses numerous coping strategies to conserve Pi utilization, while decreasing the C cost to promote nodule function during Pi stress. This could be achieved through the modulation of carbohydrate importation, mobilization of storage reserves, modification of respiratory pathways and exportation of nitrogenous (N) products. Under such circumstances, soybean regulates the C partitioning among the various nutrient-acquiring structures and the C flux through different metabolic pathways (primary and secondary). However, substantial genetic variation leading to nodule acclimation to Pi stress is notable and dependent on the crop genotypes and/or rhizobial strains that are in symbiosis. Several Pi deficiency-induced responses (e.g., mycorrhizal association, exudative burst and secondary metabolism) can act to increase the Pi levels in nodules, which are, unavoidably, often associated with a heavy burden to the overall C budget of the host. Alternative non-adenylate respiratory pathways (e.g., glycolytic bypass) and ureide export (i.e., less amide transport) are metabolically less expensive, and thus more favorable during Pi stress.

原文链接:

NSTL
Elsevier

Photoreceptor regulation of Hypericum perforatum L. (cv. Topas) flowering under different light spectrums in the controlled environment system

Karimi, MasumehAhmadi, NimaEbrahimi, Morteza

11页

查看更多>>摘要：The content of secondary metabolites in medicinal plants is affected by several internal and external stimuli. Light quality is regarded as one of the considerable environmental factors affecting plant photomorphogenesis processes and bio-active compounds biosynthesis. There is a great demand for high-quality medicinal plants and plant factory systems would be helpful in response to this demand. But, before using these systems, the light spectrum required for each species must be determined. So, in this study the Hypericum perforatum L. cv. Topas plantlets were subjected to six red (R) to blue (B) light ratio treatments including 100 R:0B, 80 R:20B, 50 R:50B, 20 R:80B, 0 R:100B, and white LED was considered as control. Among the six various light treatments, plants grown under 100% red LED showed the highest fresh and dry weight of flowers, foliage and roots. The total shoot number, flowering shoot number, and flower number were significantly (P < 0.05) affected by red light spectrum, while the blue light LED and especially monochromatic blue light resulted in growth retardation. The blue light spectrum promoted the proline concentration and oxidative stress markers such as H2O2 and MDA, whereas soluble sugars concentration was higher in plants under red LED light. The highest percentage of hypericin (4.42%/m2), pseudohypericin (8.07%/m2), and hyperforin (50.67%/m2) were detected in flowers under red light treatment, calculated based on square meter. Total phytochrome was higher in the leaves of plants under R50: B50 LED and 100 R:0B treatments. Expression of the photoreceptor and flowering-related genes HpPHYA, CRY1, CRY2, GI, CO and FTL, were affected in plants under sole red light. Molecular studies have shown that red light has a flowering-enhancing effect, in contrast, blue light has a deterrent effect on H. perforatum flowering. This corroborates that red light can promote H. perforatum growth and flowering by inducing morphological, physiological and molecular responses.

原文链接:

NSTL
Elsevier

Adaptation of inorganic carbon utilization strategies in submerged and floating leaves of heteroblastic plant Ottelia cordata

Wang, ShaoningLi, PengpengLiao, ZuyingWang, Wanwan...

11页

查看更多>>摘要：During the life history, the aquatic heteroblastic plant undergoes submerged-leaf and floating/emerged-leaf phases, with dramatic changes in their surrounding environments. However, little is known about the physiological and biochemical changes of the two types of leaves adapting to submerged and aerial environments. In the present study, a heteroblastic plant Ottelia cordata was chosen to investigate the variations in morphology, anatomy, physiology, and biochemistry between the two types of leaves. The results showed that the floating leaf developed stomate to absorb atmospheric CO2 for photosynthesis to adapt to the aerial habitat, while the submerged leaf showed longer, narrower, and thinner to maximize inorganic carbon uptake underwater. Through external carbonic anhydrase catalysis, both types of leaves could use HCO3- as an extra carbon source, and it was stronger in submerged leaves. Besides HCO3- use, the delta C-13 and the activity of C4 process key enzymes supported that the submerged leaf could perform C4 metabolism, while the floating leaves only carried on C3 metabolism. This is the first time to report an aquatic plant transiting from the C4 process underwater to the C3 process in the air. Based on the discrimination of stable carbon isotope, in the field, the main carbon source was atmospheric CO2 for floating leaves and the free CO2 underwater for submerged leaves. Additionally, HCO3- could approximately support 16% carbon source for underwater photosynthesis, which was the second important carbon source for submerged leaves. All our data indicated the heteroblastic aquatic plant adapts to underwater and aerial environments in morphology, anatomy, physiology, and biochemistry for completing life history and maintaining the population in the field.

原文链接:

NSTL
Elsevier